Method for manufacturing electronic component device with a ni-bi alloy sealing frame

ABSTRACT

An electronic component device having a first sealing frame formed on a main substrate and a second sealing frame formed on a cover substrate, the first and second sealing frames being composed of a Ni film. A bonding section constituted by a Ni—Bi alloy is formed between the first and second sealing frames. For example, a Bi layer is formed on the first sealing frame, and then the first sealing frame and the second sealing frame are heated at a temperature of 300° C. for at least 10 seconds while applying pressure in the direction in which the first sealing frame and the second sealing frame are in close contact with each other, and thus the bonding section, which bonds the first sealing frame to the second sealing frame, is formed.

CROSS REFERENCE TO RELATED APPLICATIONS

The present application is a divisional of application Ser. No. 13/026,540, filed Feb. 14, 2011, which is a continuation of International Application No. PCT/JP2009/064156, filed Aug. 11, 2009, which claims priority to Japanese Patent Application No. JP2008-212471, filed Aug. 21, 2008, the entire contents of each of these applications being incorporated herein by reference in their entirety.

FIELD OF THE INVENTION

The present invention relates to an electronic component device and a method for manufacturing the same, and particularly to an electronic component device having a structure of bonding sealing frames to each other for hermetic sealing, and a method for manufacturing the same.

BACKGROUND OF THE INVENTION

Electronic component devices of interest to the present invention include, for example, a BAW filter. The BAW filter includes a main substrate provided with an electronic circuit forming section and a first sealing frame surrounding the electronic circuit forming section on one main surface of the main substrate, and a cover substrate provided with a second sealing frame to be bonded to the first sealing frame on one main surface of the cover substrate. Then, the main substrate and the cover substrate are disposed so that the main surfaces of the two substrates face each other, and in this state, the first sealing frame and the second sealing frame are bonded to each other to realize a structure in which the above-mentioned electronic circuit forming section is hermetically sealed.

The following technologies have been proposed as a technology for bonding the first sealing frame and the second sealing frame to each other to seal an electronic component device as described above.

First, a sealing technology based on a Cu—Sn alloy has been proposed in Japanese Unexamined Patent Publication No. 2004-194290 (Patent Document 1) and Japanese Unexamined Patent Publication No. 2006-135264 (Patent Document 2). This sealing technology will be described with reference to FIG. 7.

In FIG. 7, a part of each of a main substrate 1 and a cover substrate 2, which are disposed so as to face each other, is shown. As shown in FIG. 7(1), a first sealing frame 3 is formed on an upper main surface of the main substrate 1, and on the other hand, a second sealing frame 4 is formed on a lower main surface of the cover substrate 2 before a bonding step is performed. The first and second sealing frames 3 and 4 are composed of, for example, copper (Cu). An oxidation resistant film 5 composed of Au, for example, is formed on the first sealing frame 3 as required as shown by the dotted line. The oxidation resistant film 5 is a film for preventing the oxidation of Cu constituting the first sealing frame 3, and does not contributes directly to bonding described later. On the other hand, a Sn layer 6 predominantly composed of Sn having a lower melting point than Cu is formed on the second sealing frame 4. The Sn layer 6 functions as a bonding material.

In order to attain a state in which the first sealing frame 3 is bonded to the second sealing frame 4, the first sealing frame 3 and the second sealing frame 4 are brought into a contact state, in which the two frames face each other with the Sn layer 6 interposed therebetween, by applying pressure, and the first sealing frame 3 and the second sealing frame 4 are heated while maintaining the contact state. Consequently, first, Au constituting the oxidation resistant film 5 is dissolved in the Sn layer 6, and then, Cu constituting the first and second sealing frames 3 and 4 diffuses into the Sn layer 6 to produce an intermetallic compound of Cu and Sn.

More specifically, when heating in pressurization as described above is continued, the Sn layer 6 disappears, and first, a Cu₆Sn₅ layer 7 predominantly composed of Cu₆Sn₅ having a melting point of 415° C. is formed as shown in FIG. 7(2), and a Cu₃Sn layer 8 predominantly composed of Cu₃Sn having a melting point of 640° C. begins to be formed between the Cu₆Sn₅ layer 7 and each of the first sealing frame 3 and the second sealing frame 4.

When the heating in pressurization is further continued, the Cu₆Sn₅ layer 7 disappears as shown in FIG. 7(3), and a bonding structure, in which a bonding section 9 bonding the first sealing frame 3 to the second sealing frame 4 is constituted by the Cu₃Sn layer 8, is attained.

In the bonding structure as describe above, it is important that the Cu₆Sn₅ layer 7 disappears and the bonding section 9 is constituted by the Cu₃Sn layer 8. The reason for this is that if the Cu₆Sn₅ layer 7 remains, the interdiffusion between Cu and Sn further proceeds so that the Cu₆Sn₅ layer 7 will change to the Cu₃Sn layer 8 when the bonding section 9 is exposed to used reflow or high-temperature environment for a long time, and so-called Kirkendall voids may be generated due to difference in diffusion coefficients between Cu and Sn during the interdiffusion proceeds to cause defective sealing.

In order to attain a state in which the Cu₆Sn₅ layer 7 disappears and the bonding section 9 is constituted by the Cu₃Sn layer 8, it is necessary to diffuse Cu adequately into Sn, but the alloy growth rate of Cu₃Sn is extremely small as shown in FIG. 8. In addition, FIG. 8 shows the growth rates of alloys at 300° C. Therefore, in order to attain a state in which the bonding section 9 is constituted by the Cu₃Sn layer 8, for example, the condition that a temperature of 300° C. is held for 60 minutes under a pressure of 8.2 Mpa is required. Therefore, this process leads to a problem that productivity is low and production cost is high. Further, the above-mentioned conditions may be extreme conditions of impairing the quality of the electronic circuit forming section included in the electronic component device.

-   Patent Document 1: Japanese Unexamined Patent Publication No.     2004-194290 -   Patent Document 2: Japanese Unexamined Patent Publication No.     2006-135264

SUMMARY OF THE INVENTION

Thus, it is an object of the present invention to provide an electronic component device capable of solving the above-mentioned problems and a method for manufacturing the same.

The present invention is first directed to a structure of an electronic component device including a main substrate provided with an electronic circuit forming section and a first sealing frame surrounding the electronic circuit forming section on one main surface of the main substrate, a cover substrate provided with a second sealing frame to be bonded to the first sealing frame on one main surface of the cover substrate, and a bonding section which bonds the first sealing frame to the second sealing frame, and in order to solve the above technical problems, the present invention has a feature that each of the first sealing frame and the second sealing frame is made of a Ni film predominantly composed of Ni and the bonding section is constituted by a Ni—Bi alloy predominantly composed of Ni and Bi.

It is preferred that the Ni—Bi alloy is NiBi.

Further, the Ni—Bi alloy may contain NiBi₃.

In a preferred embodiment of the electronic component device of the present invention, a first connecting electrode is formed at a location, surrounded by the first sealing frame, on the one main surface of the main substrate and a second connecting electrode is formed at a location, surrounded by the second sealing frame, on the one main surface of the cover substrate, and an electrically connecting section electrically connecting the first connecting electrode to the second connecting electrode is disposed and the electrically connecting section has a constitution similar to that of the bonding section.

The present invention is also directed to the method for manufacturing the electronic component device as described above.

The method for manufacturing an electronic component device of the present invention has a feature that the method includes the steps of preparing a main substrate provided with an electronic circuit forming section and a first sealing frame surrounding the electronic circuit forming section on one main surface of the main substrate, in which the first sealing frame is made of a Ni film predominantly composed of Ni; preparing a cover substrate provided with a second sealing frame to be bonded to the first sealing frame on one main surface of the cover substrate, in which the second sealing frame is made of a Ni film predominantly composed of Ni; and heating and bonding for forming a bonding section constituted by a Ni—Bi alloy predominantly composed of Ni and Bi, which bonds the first sealing frame to the second sealing frame by being the first sealing frame and the second sealing frame in close contact with each other and heating the first and second sealing frames with a Bi layer predominantly composed of Bi interposed between the first sealing frame and the second sealing frame.

In a preferred embodiment of the method for manufacturing an electronic component device of the present invention, pressure is applied in the direction in which the first sealing frame and the second sealing frame are in close contact with each other in the heating and bonding step.

It is preferred that the heating and bonding step is performed so as to form the bonding section constituted by NiBi.

Alternatively, the heating and bonding step may be performed so as to form the bonding section containing NiBi₃.

In a preferred embodiment of the method for manufacturing an electronic component device of the present invention, a first connecting electrode is formed at a location, surrounded by the first sealing frame, on the one main surface of the main substrate and a second connecting electrode is formed at a location, surrounded by the second sealing frame, on the one main surface of the cover substrate, and the step of electrically connecting the first connecting electrode to the second connecting electrode is performed concurrently with performing the heating and bonding step.

In the above preferred embodiment, it is preferred that a dimension in the width direction of at least one of the first sealing frame and the second sealing frame is larger than a dimension in the width direction of the Bi layer.

In the method for manufacturing an electronic component device of the present invention, the Bi layer is formed on any one of the first sealing frame and the second sealing frame prior to the heating and bonding step.

In accordance with the present invention, since the Ni—Bi alloy formed at the bonding section has a rapid growth rate as compared with Cu₃Sn described above, the bonding section can be formed in a short time and production cost can be reduced. Since a time for heating and bonding can be shortened, a thermal load on the electronic component device can be reduced and therefore, it becomes possible to apply the present invention to electronic component devices which are vulnerable to a high-temperature load.

Further, in accordance with the present invention, it is possible to prevent the alloy formed at the bonding section from melting, for example, in a solder reflow step since the Ni—Bi alloy has a relatively high melting point, for example, 469° C. for NiBi₃ and 654° C. for NiBi. Accordingly, the hermeticity of the electronic component device is not impaired even after the solder reflow step.

In the present invention, when the bonding section is formed so as to be constituted by NiBi, a bonding section, which is highly resistant to plastic fatigue failure due to repeated stress, can be attained.

On the other hand, in order to allow all the bonding section to be constituted by NiBi as described above, a longer heating holding time is required in the heating and bonding step, but if the bonding section is formed so as to contain NiBi₃, the heating holding time in the heating and bonding step can be shortened.

When the electronic component device of the present invention includes the first and second connecting electrodes, if the first connecting electrode is electrically connected to the second connecting electrode concurrently with performing the heating and bonding step on the first sealing frame and the second sealing frame, sealing and electrical connection can be achieved at one time, and therefore the number of steps for manufacturing the electronic component device can be decreased and the production cost can be reduced.

In the method for manufacturing an electronic component device of the present invention, if pressure is applied in the direction in which the first sealing frame and the second sealing frame are in close contact with each other in the heating and bonding step, since bonding progresses while eliminating Kirkendall voids generated due to difference in diffusion coefficients of Ni and Bi during the interdiffusion between Ni and Bi proceeds, defective sealing resulting from the Kirkendall voids remaining in the bonding section can be inhibited.

In the method for manufacturing an electronic component device of the present invention, when a dimension in the width direction of at least one of the first sealing frame and the second sealing frame is larger than a dimension in the width direction of the Bi layer, the protrusion of Bi from the bonding section can be inhibited in the heating and bonding step, and consequently undesired electric short circuit due to the protrusion of Bi can be hardly generated.

In the method for manufacturing an electronic component device of the present invention, when the Bi layer is formed on any one of the first sealing frame and the second sealing frame prior to the heating and bonding step, it is possible to attain a state in which the Bi layer is interposed between the first sealing frame and the second sealing frame by just arranging the main substrate and the cover substrate in a predetermined manner in the heating and bonding step, and therefore the production steps of the electronic component device can be efficiently performed.

BRIEF EXPLANATION OF THE DRAWINGS

FIG. 1 is a sectional view showing a BAW filter 11 as an example of an electronic component device to which the present invention can be applied.

FIG. 2 is a view for illustrating the first embodiment of the present invention and an enlarged sectional view of a first sealing frame 16 and a second sealing frame 19 shown in FIG. 1, and FIG. 2(1) shows a pre-bonding state and FIG. 2(2) shows a post-bonding state of the first sealing frame 16 and the second sealing frame 19.

FIG. 3 is a view showing stress-strain characteristics of NiBi₃ and NiBi.

FIG. 4 is a view corresponding to FIG. 2(1) for illustrating the second embodiment of the present invention.

FIG. 5 is a view for illustrating the third embodiment of the present invention and a perspective view showing a main substrate 42 and a cover substrate 43 included in an electronic component device 41 separately.

FIG. 6 is an enlarged sectional view of a bonding section of the main substrate 42 and the cover substrate 43 shown in FIG. 5.

FIG. 7 is a sectional view showing a bonding step for illustrating a conventional art of interest to the present invention.

FIG. 8 is a view showing the growth rates of alloys at 300° C., and showing the growth rate of NiBi₃, the growth rate of NiBi and the growth rate of Cu₃Sn.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 1 is a sectional view showing a BAW filter 11 as an example of an electronic component device to which the present invention can be applied.

The BAW filter 11 includes a main substrate 12 composed of, for example, silicon (Si) and a cover substrate 13 composed of, for example, borosilicate glass. The main substrate 12 and the cover substrate 13 are disposed at a predetermined distance and face each other.

An electronic circuit forming section 15 (shown in a simplified manner) to form the BAW filter circuit and a first sealing frame 16 surrounding the electronic circuit forming section 15 are formed on an upper main surface 14 of the main substrate 12. Further, several first connecting electrodes 17 leading out of the electronic circuit forming section 15 are formed at a location, surrounded by the first sealing frame 16, on the upper main surface 14 of the main substrate 12.

On the other hand, a second sealing frame 19 to be bonded to the first sealing frame 16 is formed on a lower main surface 18 of the cover substrate 13. Further, several second connecting electrodes 20 corresponding to the first connecting electrodes 17 are formed at a location, surrounded by the second sealing frame 19, on the lower main surface 18 of the cover substrate 13. Several terminal electrodes 22 are formed on an upper main surface 21 of the cover substrate 13 and each of these terminal electrodes 22 is electrically connected to a second connecting electrode 40 through a through hole conductor 23 penetrating through the cover substrate 13 in a thickness direction.

In manufacturing such a BAW filter 11, the first sealing frame 16 and the second sealing frame 19 are bonded to each other. A bonding section 24 formed by this bonding is shown in FIG. 1. The first and second sealing frames 16 and 19 extend in the form of substantial rectangle, and the electronic circuit forming section 15 is hermetically sealed when these frames are bonded to each other. Preferably, the step of electrically connecting the first connecting electrode 17 to the second connecting electrode 20 is performed concurrently with performing the step of bonding the first sealing frame 16 to the second sealing frame 19. An electrically connecting section 25 obtained by this electric connection is shown in FIG. 1, and the electrically connecting section 25 preferably has a constitution similar to that of the above-mentioned bonding section 24.

Hereinafter, several embodiments of the present invention will be described concerning the BAW filter 11 shown in FIG. 1.

FIG. 2 is a view for illustrating the first embodiment of the present invention and shows an enlarged view of a part of the first sealing frame 16 and a part of the second sealing frame 19 in FIG. 1. FIG. 2(1) shows a pre-bonding state and FIG. 2(2) shows a post-bonding state of the first sealing frame 16 and the second sealing frame 19.

With reference to FIG. 2(1), both of the first sealing frame 16 and the second sealing frame 19 are composed of a Ni film predominantly composed of Ni. Each of the widths of the first and second sealing frames 16 and 19 is, for example, 50 μm. In addition, in order to enhance adhesion between the Ni film and each of the main substrate 12 and the cover substrate 13, a Ti film, but not shown, may be formed between the Ni film and the main substrate 12 and between the Ni film and the cover substrate 13.

A Bi layer 26 predominantly composed of Bi is formed on the first sealing frame 16. An oxidation resistant film 27 composed of Au is formed between the first sealing frame 16 and the Bi layer 26 as required as shown by the dotted line. On the other hand, an oxidation resistant film 27 composed of Au, for example, is formed on the second sealing frame 19 as required as shown by the dotted line. The oxidation resistant film 27 is a film for preventing the oxidation of Ni constituting the first sealing frame 16 and the second sealing frame 19, and does not contributes directly to bonding described later. The Ni film, the Bi layer 26 and the oxidation resistant film 27 composed of Au, which become layers on the first sealing frame 16 and the second sealing frame 19, are formed, for example, by vapor deposition, plating or the like.

In order to attain the structure shown in FIG. 2(2) described later, the thickness of the Ni film constituting each of the first and second sealing frames 16 and 19 is determined in such a way that a total volume of Ni supplied from the first and second sealing frames 16 and 19 is 34.6% or more of a volume of the Bi layer 26 supplied. As an example, when the thickness of the Bi layer is 5 μm, the Ni film constituting each of the first and second sealing frames 16 and 19 is set so as to be 1.73 μm or more in the total thickness.

The oxidation resistant film 27 composed of Au may have a sufficient thickness for performing the function of preventing oxidation.

In addition, in the embodiment shown in FIG. 2(1), the Bi layer 26 is formed on the first sealing frame 16, and the oxidation resistant film 27 is formed on the second sealing frame 19, but the positions of the Bi layer 26 and the oxidation resistant film 27 may be reversed. Further, the Bi layer 26 may be formed on both the first sealing frame 16 and the second sealing frame 19.

Next, the heating and bonding step for forming a bonding section 24, which bonds the first sealing frame 16 to the second sealing frame 19, is performed by heating while applying pressure in the direction in which the first sealing frame 16 and the second sealing frame 19 are in close contact with each other with the Bi layer 26 interposed between the first sealing frame 16 and the second sealing frame 19. Au constituting the oxidation resistant film 27 is dissolved in the Bi layer 26 at an initial stage of the heating and bonding step. Further, a state after performing the heating and bonding step is shown in FIG. 2(2).

The above-mentioned heating and bonding step is performed in a nitrogen atmosphere in which an oxygen concentration is, for example, 100 ppm or less. In addition, the atmosphere in the heating and bonding step may be an atmosphere of inert gas other than nitrogen, or may be a reducing atmosphere or vacuum. An application of pressure in the heating and bonding step has an effect of accelerating wetting of the second sealing frames 16 composed of the Ni film by Bi contained in the Bi layer 26, and an effect of suppressing the formation of voids at the time of forming alloys, and for example, a surface pressure of 8 Mpa is applied. However, when the oxide film formed on the surface of the Ni film is removed by a physical treatment such as plasma etching or a chemical treatment and then bonding is performed without being exposed to an oxidizing atmosphere, bonding can be performed without applying pressure. Further, a peak temperature in the heating and bonding step is set at 271° C. at which Bi is melted or more.

For example, when the thickness of the Bi layer 26 is 5 μm, the whole Bi layer 26 can be converted to a bonding section 24 constituted by a Ni—Bi alloy as shown in FIG. 2(2) by just retaining the layer at a peak temperature of 300° C. for at least 10 seconds. When the Ni—Bi alloy formed at the bonding section is NiBi₃, the bonding section 24 has a melting point of 469° C., and when the Ni—Bi alloy formed at the bonding section is NiBi₃, the bonding section 24 has a melting point of 654° C., and therefore it is possible to prevent the bonding section from melting, for example, in a solder reflow step. Accordingly, the hermeticity of the BAW filter is not impaired even after the solder reflow step.

In addition, the above-mentioned peak temperature and peak retention time vary in optimum values, respectively, depending on the thickness of the Bi layer 26, a temperature raising rate and a cooling rate.

The alloy growth rates of NiBi₃ and NiBi at 300° C. of the Ni—Bi alloys are shown by “NiBi₃” and “NiBi” in FIG. 8. As is evident from FIG. 8, since both of NiBi₃ and NiBi have a rapid growth rate as compared with Cu₃Sn described above, the alloy can be formed in a short time and therefore production cost can be reduced.

Further, if making growth rate comparisons between NiBi₃ and NiBi, the growth rate of NiBi₃ is more rapid than that of NiBi. As is evident from this, when NiBi₃ is produced at an initial stage of the heating and bonding step and then the heating and bonding step is continued, the diffusion of NiBi₃ and NiBi proceeds and the whole bonding section becomes NiBi. The whole bonding section 24 can be converted to NiBi by retaining the section at a peak temperature of 300° C. for 400 seconds for example when the thickness of the Bi layer 26 is 5 μm, although the result varies depending on the thickness of the Bi layer 26, a temperature raising rate and a cooling rate.

Hardness and elastic modulus of NiB₃ was compared with those of NiBi, and consequently NiB₃ had a hardness of 1300 N/mm² and an elastic modulus of 50 GPa and NiBi had a hardness of 3650 N/mm² and an elastic modulus of 100 GPa, and therefore both of the hardness and the elastic modulus of NiBi are larger than those of NiB₃. Since hardness is approximately proportional to tensile strength, it is said that NiBi is a material tougher than NiB₃.

FIG. 3 shows stress-strain characteristics of NiBi₃ and NiBi. As shown in FIG. 3, an elastic region of NiBi is broader than that of NiB₃.

Accordingly, since NiBi₃ has a narrower elastic region, NiBi₃ is deformed plastically even if the same strain is applied, and a permanent strain may remain even when stress is 0. Therefore, when repeated stress is applied in a thermal impact test or the like, the permanent strain may be accumulated, resulting in fracture.

On the other hand, since NiBi has a broader elastic region, NiBi is deformed elastically even if strain which causes a plastic deformation in NiB₃ is applied to NiBi, and NiBi is returned to an original state if stress is 0 and a permanent strain does not remain. Therefore, NiBi stores most of a load generated due to thermal stress as elastic energy to hardly cause a plastic strain and is highly resistant to plastic fatigue failure due to repeated stress.

As described above, when the bonding section 24 is formed so as to be constituted by NiBi, the bonding section 24 can be highly resistant to plastic fatigue failure due to repeated stress.

On the other hand, if the bonding section 24 is formed so as to contain NiBi₃, the heating holding time in the heating and bonding step can be shortened.

FIG. 4 is a view corresponding to FIG. 2(1) for illustrating the second embodiment of the present invention. In FIG. 4, the same reference symbols are given to elements corresponding to the elements shown in FIG. 2, and overlapped descriptions are omitted.

The second embodiment has a feature that a dimension W2 in the width direction of the second sealing frame 19 is larger than a dimension W1 in the width direction of the first sealing frame 16. This is a configuration for preventing Bi constituting the Bi layer 26 from protruding from the first sealing frame 16 due to the pressurization in the heating and bonding step to cause electric short circuit between the protruded Bi and the connecting electrode 20, for example. As an example, when the dimension W2 in the width direction of the second sealing frame 19 is 50 μm, the dimension W1 in the width direction of the first sealing frame 16 is set at about 15 to 25 μm.

In addition, in the embodiment shown in FIG. 4, at the first sealing frame 16, a Cu film 32 predominantly composed of Cu is formed in a thickness of 7.5 μm or more, for example, including the thickness of Ni film by a thick film formation technology before a Ni film 31 is formed. By forming a relatively thick Cu film 32 as described above, an effect of preventing the protrusion of Bi is enhanced. Further, by forming the thick Cu film 32, it can be expected to lessen thermal stress generated due to difference in coefficients of thermal expansion between the first member and the second member. However, if such an advantage is not particularly desired, the Ni film 31 may be formed directly on the main substrate 12 omitting the Cu film 32.

In FIG. 4, the dimension W2 in the width direction of the second sealing frame 19 is larger than the dimension W1 in the width direction of the first sealing frame 16, but conversely, the dimension W1 in the width direction of the first sealing frame 16 may be larger than the dimension W2 in the width direction of the second sealing frame 19. However, a dimension in the width direction of the Bi layer 26 is matched with smaller one of the dimensions W1 and W2 in the width direction. The Bi layer 26 may be formed on any of the first sealing frame 16 and the second sealing frame 19.

Further, when Bi protrudes as described above, Bi tends to cohere in corner sections of the sealing frames 16 and 19, and therefore the corner sections are preferably formed into a circular arc shape in order to suppress such cohesion.

The above-mentioned constitution in the bonding section 24 which bonds the first sealing frame 16 to the second sealing frame 19 can be applied similarly to the electrically connecting section 25 which electrically connects the first connecting electrode 17 to the second connecting electrode 20. In this case, if the connecting step of electrically connecting the first connecting electrode 17 to the second connecting electrode 20 is performed concurrently with performing the heating and bonding step on the first sealing frame 16 and the second sealing frame 19, sealing and electrical connection can be achieved at one time, and therefore, the number of steps for manufacturing the BAW filter 11 can be decreased and the production cost can be reduced.

Further, the constitution for suppressing the protrusion of Bi, described with reference to FIG. 4, can also be applied to the connecting electrodes 17 and 20 as described above.

Further, the present invention can be applied not only to the BAW filter 11 including the main substrate 12 provided with the first sealing frame 16 and the cover substrate 13 provided with the second sealing frame 19, but also to other electronic component devices including similar main substrates and cover substrates.

In the method for manufacturing an electronic component device of the present invention, a first collective substrate which gives a plurality of main substrates, and a second collective substrate which gives a plurality of cover substrates are prepared, and the heating and bonding step may be performed in a state of the first collective substrate and the second collective substrate. In this case, after the heating and bonding step, a step, in which the first collective substrate and the second collective substrate are divided into each electronic component device unit, is further performed. In the heating and bonding step, it is preferable to use a chamber in which an inert gas can be introduced or a vacuum atmosphere can be produced while housing the first and second collective substrates. In accordance with such a manufacturing method, since a plurality of electronic component devices can be manufactured by one operation, the productivity improvements of the electronic component device can be expected.

Further, a cap-shaped substrate shown in FIG. 5 may be used for the cover substrate. FIG. 5 is a view for illustrating the third embodiment of the present invention and a perspective view showing a main substrate 42 and a cover substrate 43 included in an electronic component device 41 separately. FIG. 6 is an enlarged sectional view of a bonding section of the main substrate 42 and the cover substrate 43 shown in FIG. 5. In FIG. 5, the same reference symbols are given to elements corresponding to the elements shown in FIG. 2(1), and overlapped descriptions are omitted.

On an upper main surface 14 of the main substrate 42, an element 44 to form a required circuit is mounted and the first sealing frame 16 surrounding the element 44 is formed. In addition, a connecting conductor to be lead out of the element 44 is omitted in FIG. 6.

On the other hand, a recessed section 46 (refer to FIG. 6) is formed on a lower main surface of the cap-shaped cover substrate 43, and the second sealing frame 19 to be bonded to the first sealing frame 16 is formed on a lower side of a peripheral section 47 which defines the recessed section 46.

With reference to FIG. 6, both of the first sealing frame 16 and the second sealing frame 19 are constituted by a Ni film predominantly composed of Ni.

The oxidation resistant film 27 composed of Au is formed on the first sealing frame 16 as required. On the other hand, the Bi layer 26 predominantly composed of Bi is formed on the second sealing frame 19.

In addition, an arrangement of the oxidation resistant film 27 on the first sealing frame 16 and the Bi layer 26 on the second sealing frame 19 and the like may be modified as other embodiments. For example, the Bi layer 26 may be formed on the main substrate 42 side.

Further, also in this embodiment, the main substrate 42 is prepared in a state of a collective substrate constituting a plurality of main substrates 42, and the main substrate 42 may be bonded to the cover substrates 43 in the state of a collective substrate, and then divided into each main substrate 42, or may be bonded to the cover substrate 43 in a state of each main substrate 42.

DESCRIPTION OF REFERENCE SYMBOLS

-   -   11 BAW filter (electronic component device)     -   12, 42 main substrate     -   13, 43 cover substrate     -   15 electronic circuit forming section     -   16 first sealing frame     -   17 first connecting electrode     -   19 second sealing frame     -   20 second connecting electrode     -   24 bonding section     -   25 electrically connecting section     -   26 Bi layer     -   41 electronic component device 

1. A method for manufacturing an electronic component device, the method comprising: preparing a main substrate provided with an electronic circuit forming section and a first sealing frame surrounding said electronic circuit forming section on a surface of the main substrate, said first sealing frame comprising a Ni film predominantly composed of Ni; preparing a cover substrate provided with a second sealing frame to be bonded to said first sealing frame on a surface of the cover substrate, said second sealing frame comprising a Ni film predominantly composed of Ni; interposing a Bi layer predominantly composed of Bi between said first sealing frame and said second sealing frame; and heating and bonding said first sealing frame to said second sealing frame so as to form a bonding section constituted by a Ni—Bi alloy predominantly composed of Ni and Bi.
 2. The method for manufacturing an electronic component device according to claim 1, wherein pressure is applied in a direction in which said first sealing frame and said second sealing frame are in close contact with each other in said heating and bonding step.
 3. The method for manufacturing an electronic component device according to claim 1, wherein said heating and bonding step is performed so as to form said bonding section constituted by NiBi.
 4. The method for manufacturing an electronic component device according to claim 1, wherein said heating and bonding step is performed so as to form said bonding section containing NiBi₃.
 5. The method for manufacturing an electronic component device according to claim 1, further comprising: forming a first connecting electrode on said surface of said main substrate at a location surrounded by said first sealing frame; forming a second connecting electrode on said one main surface of said cover substrate at a location surrounded by said second sealing frame; and electrically connecting said first connecting electrode to said second connecting electrode concurrently with said heating and bonding step.
 6. The method for manufacturing an electronic component device according to claim 1, wherein a width of at least one of said first sealing frame and said second sealing frame is larger than a width of said Bi layer.
 7. The method for manufacturing an electronic component device according to claim 1, further comprising forming said Bi layer on any one of said first sealing frame and said second sealing frame prior to said heating and bonding step. 